Recombinant antigens for diagnosis and prevention of murine typhus

ABSTRACT

The invention relates to the construction of recombinant, immunodominant  Rickettsia typhi  proteins. The invention also relates to a method for the use of the recombinant proteins, either singly or in combination, in detection and diagnostic assays. The proteins can also be used in anti- Rickettsia typhi  immunogenic formulations.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application claims priority to U.S. Provisional application 60/793,583 filed Apr. 20, 2006.

SEQUENCE LISTING

I hereby state that the information recorded in computer readable form is identical to the written sequence listing.

BACKGROUND OF THE INVENTION

1. Field of the Invention

This invention relates to a gene and protein which can be used for vaccination against and/or for the detection and identification of R. typhi. More particularly, the invention relates to a specific nucleotide sequence encoding a highly specific and immunogenic portion of the gene encoding the protective S-layer protein antigen of Rickettsia prowazekii and the polypeptide products of this gene. The polypeptide sequence can be utilized in diagnostic and detection assays for murine typhus and as an immunogen useful as a component in vaccine formulations against murine typhus.

2. Description of the Prior Art

Murine (endemic or flea-borne) typhus, caused by infection with Rickettsia typhi, is a zoonosis that involves rats (Rattus rattus and R. norvegicus) as the main reservoir and the oriental rat flea (Xenopsylla cheopis) as the main vector [1,2]. The infection is primarily caused by scratching the flea bitted site and self-inoculating the R. typhi-laden feces, or directly by infected flea bite [3]. The symptoms of murine typhus include fever, headache, enlarged local lymph nodes and rashes on the trunk. These clinical manifestations are non-specific and resemble many other diseases such as viral infections, typhoid fever, leptospirosis, epidemic typhus and scrub typhus [3,10]. As a result, murine typhus is frequently misdiagnosed and its incidence is probably grossly underestimated.

Murine typhus is one of the most widely distributed arthropod-borne diseases of humans and occurs in a variety of environments from hot and humid lowlands to semi-arid highlands including Australia [6], Spain [7], Indonesia [8], and southwestern United States [9] in addition to previously reported countries including China, Thailand, Kuwait, Israel, and Vietnam [3,5]. It is often found in international port cities and costal regions where rodents are common [3-5].

The diagnosis of murine typhus relies mainly on serological methods [11]. The old serological assay, Weil-Felix test, is based on the detection of antibodies to Proteus vulgaris OX-19 that contains cross reactive epitopes of Rickettsia [12, 13]. However, determination of R. typhi infection by the Weil-Felix test requires a qualitative determination and therefore somewhat subjective. Additionally, because the Weil-Felix reaction requires specialized reagents, many facilities especially in rural areas or in developing countries often may not be capable of performing the laboratory diagnosis.

Other techniques include immuno-fluorescence assay (IFA) and complement fixation (CT) tests were adapted for the detection of antibodies specific for rickettsiae [14-16]. Current serodiagnostic assays such as the ELISA, Dip-S-Ticks (DS), indirect immunofluorescent antibody (IFA) and indirect peroxidase assays [17,18] require the propagation of rickettsiae in infected yolk sacs of embryonated chicken eggs or cell cultures to prepare the antigens used in these assays. However, only a few specialized laboratories have the ability to culture and purify rickettsiae, which requires Biosafety level three (BSL-3) containment facilities. Additionally, because the organism is required for the assay, in addition to potential biosafety hazards associated with the assay, these assay methods also suffer from refrigerated storage requirements, and the problem of reproducibility associated with frequent production of rickettsial antigens.

In addition to antibody-based assays, polymerase chain reaction (PCR) amplification of rickettsial protein antigen genes has been demonstrated as a reliable diagnostic method, and genotypes can be determined without isolation of the organism [19,20]. However, gene amplification requires sophisticated instrumentation and reagents generally not available in most medical facilities especially those far forward. Based on these considerations, production of recombinant antigens of R typhi is a logic direction for the development of serological assays and vaccine candidates for murine typhus.

R. typhi has a monomolecular layer of protein arranged in a periodic tetragonal array on its surface [21]. This crystalline layer, representing 10 to 15% of the total protein mass of the rickettsia, was identified as the immunodominant species-specific surface protein antigen OmpB. It has been isolated, purified, and biochemically characterized [22-25]. The earliest and dominant immunological responses in mice, guinea pigs, rabbits, and humans, following infection with R. typhi, are directed against Omp B [17, 4, 25]. We have shown that purified native typhus OmpB induces strong humoral and cell mediated immune responses. Protective immunity was elicited by typhus OmpB in guinea pig and mouse protection models [26-29].

Based on these observations, therefore, OmpB is a particularly advantageous target for developing diagnostic reagents. R. prowazekii, the etiologic agent of epidemic typhus, also belongs to the typhus group of rickettsiae and its OmpB exhibits similar antigenic and chemical structures to those of R. typhi. Therefore, cross-reactivity of antibody to OmpB between these two species is inevitable. Cross absorption of test serum is needed to distinguish between them these to species [10].

The whole ORF of OmpB codes for a polypeptide of 1642 amino acids. The native matured protein does not contain the leader peptide at the N-terminus and the β-sheet peptide at the C-terminus. The expression of the intact OmpB protein (135 kDa) has been attempted. However, the full-length product was shown to be toxic to Escherichia coli and rapidly degraded. Moreover, due to its large size and high contant of β-sheet structure, refolding of the full-length gene product was not successful.

SUMMARY OF THE INVENTION

Accordingly, an object of this invention are methylated and unmethylated recombinant polypeptides encompassing immunologically active regions of OmpB of Rickettsia typhi.

Another object of the invention is a method of using the methylated or unmethylated recombinant OmpB fragments in antibody-based assays for the detection of exposure to Rickettsia typhi.

A still further object of the invention is the use of OmpB or the OmpB fragments as an immunogen.

BRIEF DESCRIPTION OF DRAWINGS

FIG. 1. Open reading frame of OmpB and location of Fragments A, K and AN.

FIG. 2. Western blot analysis of native and recombinant antigens.

DESCRIPTION OF THE PREFERRED EMBODIMENTS

Evaluation of Rickettsia typhi proteins has led to the identification of OmpB is an exceptionally promising candidate as a reagent for use in diagnostic and detection assays as well as components in vaccine formulations. The species-specific surface protein antigen OmpB of R. typhi was identified as the immunodominant. The earliest and dominant immunological anti-protein responses of mice, guinea pigs, rabbits, and humans following infection with R. typhi are directed against this Omp B antigen. These observations suggested OmpB as an appropriate target for developing diagnostic reagents.

Central to the development of improved detection and diagnostic immunoassay methods and standardization is the development of more effective antigens for use in existing antibody-based methods. In order to improve the antigenicity and potential immunogencity of the OmpB, specific regions of OmpB were evaluated for sera reactivity. Western blot analysis of partially digested OmpB revealed that all the reactive fragments were larger than 20 kDa [31]. One reactive fragment was located at the N-terminus and another located at the C-terminus. Along these lines, efforts have been made to identify immunodominant fragments of OmpB proteins. Accordingly, two highly sera-reactive protein fragments (Fragment A and Fragment K) have been identified. FIG. 1 illustrates the location of these fragments within the OmpB molecule. The amino acid sequence of OmpB is illustrated in SEQ ID No. 10, which is encoded by nucleotide the sequence of SEQ ID No. 11. Also identified is Fragment AN, which encompasses Fragment A. The location Fragment AN, which has the amino acid sequence of SEQ ID No. 9 and is encoded by nucleotide sequence SEQ ID No. 12, is also illustrated in FIG. 1.

Fragment A and Fragment K of OmpB from R. typhi were successfully cloned, expressed, purified, and refolded. Both fragments have been shown to be recognized by different patient sera and can be used to replace whole cell antigens and/or native OmpB as a diagnostic marker and a potential vaccine candidate. The reactivity of Fragment A has been increased by methylation. The reactivity of Fragment K with patient sera was not as good as that of native OmpB, it is possibly due to the fact that Kt covers only ½ of the whole OmpB. The improvement may be made by methylation of the fragment K and/or combining A and K to provide more reactive epitopes.

Construction of recombinant R. typhi protein A Fragment was carried out by first producing a cDNA copy of the gene sequence by polymerase chain reaction. A primer pair was designed using the nucleotide sequence of the ORF of R. typhi OmpB. The forward primer (SEQ ID No. 5) contained the methionine initiation codon, at residue 33, which is part of the Nde I recognition sequence. The reverse primer (SEQ ID No. 6) mutated the lysine codon at residue 273 to a stop codon and contained a Bam HI site. Fragment A has the amino acid sequence of SEQ ID No. 2 and is encoded by the nucleotide sequence of SEQ ID No. 1.

The coding sequence from amino acid 33 to 272 was amplified by PCR from DNA isolated R. typhi Wilminton strain. The fragment A gene was amplified in a mixture of 400 mM each of deoxynucleotide triphosphate, 1 μM of each primer, 1.5 U of Taq polymerase (Perkin Elmer-Cetus, Norwalk Conn.) in 10 mM Tris-HCl buffer, pH 8.3, 1.5 mM MgCl₂, and 50 mM KCl. The PCR reaction was started with 5 min at 94 C, and followed by 30 cycle of 94 C for 50 second, 55 C for 1 min and 72 C for 2 min. the last cycle was extended for 10 min at 72 C. the amplified gene fragment was digested with Nde I (New England BioLabs, Beverly, Mass.) and BamH I (GIBCO-BRL Life Technology, Gaithersburg, Md.) and ligated with doubly digested expression vector pET11a.

Fragment A was expressed as inclusion body in E. coli BL21. The inclusion bodies were extracted with 2 M urea twice followed by 2% deoxycholate twice. The final pellet was dissolved in 8 M urea and refolded by sequential dialysis in decreasing concentrations of urea. The chemical methylation of fragment A was performed according to the procedures described by Taralp and Kaplan (J. Prot. Chem. 16, 183-193, 1997).

For construction of fragment K, a primer pair was designed using the nucleotide sequence of the ORF of R. typhi OmpB. The forward primer (SEQ ID No. 7) contained the arginine residue 745 codon AGG and changed to ATG as the initiation codon for methionine, which is part of the Nde I recognition sequence. The reverse primer (SEQ ID No. 8) mutated the serine 1354 TCA to a stop codon TAA and contained a Bam HI site. Fragment K has amino acid sequence of SEQ ID No. 4 and is encoded by the DNA sequences of SEQ ID No. 3.

The coding sequence from amino acid 745 to 1353 was amplified by PCR from DNA isolated R. typhi Wilminton strain. The fragment K gene was amplified in a 50 ul mixture of 150 mM each of deoxynucleotide triphosephate, 0.8 μM of each primer, 2.5 U of Taq Gold polymerase (Perkin Elmer-Cetus, Norwalk Conn.) in 10 mM Tris-HCl buffer, pH 8.3, 1.5 mM MgCl₂, and 50 mM KCl. The PCR reaction was started with 10 min at 94 C, and followed by 30 cycle of 94 C for 30 second, 55 C for 30 second and 72 C for 2 min. the last cycle was extended for 7 min at 72 C. The ligation of the amplified fragment K in to pET11a was the same as for fragment A.

Fragment K was over-expressed in BL21 cells by induction with 1 mM IPTG for 4 hr. The over-expressed K was primarily in the inclusion body and was extracted with 4 M urea. The solubilized K in 4 M urea was further purified with HPLC using two gel filtration columns in tandem (TSK-G3000-SW and TSK-G4000-SW) followed by an anion exchange column using a NaCl gradient (50-100 mM in 30 minutes). A greater than 95% purity as demonstrated by SDS-PAGE. The purified K was refolded by dialysis in 2 M urea at 4° C. with two changes of dialysis solution in the presence of reduced glutathione (1 mM), followed by dialysis in buffer without urea.

Expression of Fragment A and K was accomplished by inserting the encoding DNA into a suitable expression system, such as pET 24a. The R. typhi recombinant protein antigen can be utilized as an antigen either as an unpurified E. coli lysate or purified by any number of methods and subsequently used as antigen in detection or diagnostic assays.

In order to ascertain if antigenicity of the fragments could be positively affected by methylation, Fragment A, located at the N-terminus (aa 33-273) was expressed in E. coli, purified, refolded, and then chemically methylated in vacuum using CH3I. The sites of multiple methylation, mon-, di-, tri-methylation were characterized by liquid chromatography/Mass Spectroscopy (LC/MS) [32].

FIG. 2 illustrates the specificity of the recombinant Fragment K by western blot analysis. In FIG. 2, no reactivity was observed against OmpA or OmpB using control sera. However, both OmpA and B from Rickettsia rickettsii are clearly identifiable using anti-R. rickettsii sera (Panel B). The lack of response in lane two of Panel B likely indicates that folding in the OmpAB chimera abrogates normally available epitopes. These same proteins were observed when anti-R. prowazekii sera was used, illustrating the presence of cross-reactive epitopes between R. rickettsii and R. prowazekii. However, anti-R. typhi sera only bound to Fragment K but not OmpA or OmpB from R. rikettsii (Panel D).

These studies demonstrated a significant increase in sero-reactivity of fragment A (i.e., Fragment A from R. typhi) subsequent to chemical methylation, compared to unmethylated Fragment A. The reader is referred to Table 1, showing enzyme-linked immunosorbent assay (ELISA) results of 48 R. typhi immune sera on Fragment A, before and after methylation. As shown in Table 1, a robust anti-Fragment A reactivity is evident, especially for IgG, in comparison to sera responses against LPS as antigen. Recent evaluation of this methylated fragment A has shown that more than 50% of 37 confirmed positive sera with whole cell antigen were reactive, indicating that although fragment A contains important diagnostic epitopes. The results also indicate that other important epitopes are located within OmpB but not contained in Fragment A. These initial results strongly suggest that recombinant protein fragments encompass the other parts of OmpB is necessary and methylation of the recombinant proteins, either chemically or enzymatically, can increase the sensitivity of the serodiagnosis.

TABLE 1 ELISA titers from fragment A of R. typhi IgG IgM Before After Before After Patient R. typhi Meth- meth- R. typhi meth- meth- sera LPS ylation ylation LPS ylation ylation 1 800 800 400 12800 1600 400 2 800 800 800 0 100 100 3 0 100 0 0 800 800 4 100 800 800 0 800 800 5 0 800 0 12800 100 400 6 100 800 1600 100 200 12800 7 0 100 0 12800 400 1600 8 1600 800 800 12800 400 1600 9 0 100 0 12800 1600 6400 10 0 200 0 100 400 800 11 100 100 100 6400 400 400 12 nt 0 100 12800 400 400 13 nt 0 100 12800 200 800 14 3200 6400 3200 100 100 100 15 1600 6400 1600 0 200 200 16 0 200 0 0 100 400 17 0 100 0 0 100 400 18 Nt 200 0 Nt 100 200 19 100 200 12800 1600 6400 51200 20 400 1600 800 800 800 100 21 800 1600 1600 12800 800 100 22 0 800 0 0 100 100 23 0 400 0 0 0 0 24 0 200 100 200 1600 3200 25 0 200 100 3200 1600 1600 26 200 3200 6400 0 6400 6400 27 100 1600 1600 0 800 800 28 0 200 100 0 800 400 29 0 200 200 0 800 400 30 0 1600 0 1600 200 100 31 200 3200 51200 12800 200 800 32 400 6400 6400 0 100 1600 33 400 6400 6400 0 0 1600 34 100 400 400 0 0 0 35 800 200 800 0 0 0 36 1600 800 1600 12800 800 6400 37 0 400 3200 12800 800 25600 37 400 400 400 0 100 100 39 800 1600 800 400 100 100 40 800 800 800 0 100 800 41 800 1600 3200 0 200 1600 42 12800 1600 1600 12800 100 100 43 12800 1600 1600 12800 0 100 44 0 1600 0 12800 800 1600 45 200 6400 6400 12800 800 1600 46 400 3200 6400 400 400 1600 47 200 3200 3200 200 800 1600 48 800 800 3200 800 800 3200 49 800 3200 12800 800 1600 51200 50 400 1600 6400 400 800 12800 51 NT 400 800 NT 800 400

Based on these results, these protein fragments will be valuable antigens in detection and diagnostic assays. Standardization of antigen will improve assay diagnostic performance and provide early and more accurate treatment regimens. Improved sensitivity can be achieved by combination of protein fragments containing a greater number of epitopes well represented in serum antibody repertoires.

Accordingly, an aspect of this invention is the recombinant expression of immunodominant fragments of an outer membrane protein OmpB. Another aspect of this invention is the methylation of recombinant protein fragments to mimic the rickettsial derived OmpB for increased seroreactivity. Therefore, these protein fragments, recombinantly produced and either used alone or in combination will confer improved standardization and concomitant assay reproducibility and potentially sensitivity in assays for the detection and diagnostic assays for R. typhi infection and murine typhus.

The following examples are provided to further illustrate the use of the invention.

EXAMPLE 1 Use of OmpB Fragments A and K as Diagnositic Reagent

Assays using the recombinantly produced proteins include antibody-based assays such as enzyme-linked immunosorbent assays. As previously mentioned, antigen for the assay can be in the form of unpurified E. coli lysate. However, for increased assay sensitivity and reduced background, purified recombinant R. typhi proteins can be used and in methylated form. As an illustration, the following procedure is provided, comprising the following steps:

-   -   1. Recombinant proteins represented by SEQ ID No. 2, 4, 9 or 10         are immobilized, such as in 96-well plates. Alternatively, for         increased sensitivity and specificity of the assay, both of the         recombinant proteins represented by SEQ ID No. 2, 4, 9 or 10 can         be included together or immobilized separately but used in the         same assay;     -   2. Wash off unreacted/unbound antigen. A preferred embodiment of         the inventive method is to wash at least 3 times with wash         buffer containing 0.1% polysorbate surfactant such as         polyoxyethylene (20) sorbitan monolaurate;     -   3. Block unreacted sites. In a preferred embodiment, blocking of         unreacted sites is accomplished with 5% skim milk in wash         buffer) X 45 minutes and then rinsed three times.     -   4. React test sera to the bound antigen;     -   5. Plates are washed three times with wash buffer;     -   6. After incubating the test sera, the bound antibody-antigen is         exposed to a probe. In a preferred embodiment, the probe is         enzyme-labeled (e.g. peroxidase) anti-human immunoglobulin;     -   7. detecting bound probe. Detection of bound probe can by any         number of methods. In a preferred embodiment, detection is by         measurement of enzymatic reaction of added substrate.

The above specific procedural outline is provided to illustrate the general method of using the fragments for the detection R. typhi infection. However, other iterations of the general antibody-based procedure is contemplated. Furthermore, a standard curve can be constructed by conducting the above ELISA procedures with the recombinant proteins but utilizing a range of concentrations of specific antibody to R. typhi. The extent of measured binding of patient serum antibody is compared to a graphic representation of the binding of the R. typhi-specific antibody concentrations.

EXAMPLE 2 Prophetic Use of Recombinant R. typhi Proteins as a Vaccine Component

The recombinantly produced polypeptides, because of their immunoreactivity to antibody in patient sera are excellent vaccine candidates. Accordingly, all or a fragment of the R. typhi proteins: Fragment A, Fragment K or Fragment AN (SEQ ID No. 2, 4, or 9 respectively), or their respective DNA sequences (SEQ ID No. 1, 3 and 12) incorporated into a suitable expression vector system, can be utilized as vaccine components. The method for induction of R. typhi immunity contains the following steps:

-   -   a. administering an immunogenic composition containing the         entire or immunogenic fragments of the recombinant polypeptides         selected from the group consisting of SEQ ID No. 2, 4 or 9 in a         unit dose range of 50 μg to 2 mg;     -   b. administration of boosting dose of said immunogenic         composition at least 1 week after priming dose with unit dose         range of 50 μg to 2 mg in a buffered aqueous solution, wherein         an immune response is elicited.

An alternative method of immunizing is to administer DNA sequences encoding Fragments A, K or AN, or combinations thereof, inserted into a suitable expression system capable of expressing the fragments in vivo. Suitable expression systems can include viral expression vectors as well as a number of available DNA vector systems.

REFERENCES

-   1. Ito, S., J. W. Vinson & T. J. McGuire, Jr. 1975. Murine typhus     Rickettsiae in the oriental rat flea. Ann. N.Y. Acad. Sci. 266:     35-60 -   2. Farhang-Azad, A., R. Traub & C. L. Wisseman, Jr. 1983. Rickettsia     mooseri infection in the fleas Leptopsylla segnis and Xenopsylla     cheopis. Am. J. Trop. Med. Hyg. 32: 1392-1400 -   3. Azad AF. Epidemiology of murine typhus. Annu Rev Entomol 1990;     35:553-69. -   4. Kelly D J, Richards A L, Temenak J J, Strickman D, Dasch G A. The     past and present threat of rickettsial diseases to military medicine     and international public health. Clin Infect Dis 2002; 34(suppl     4):s145-s169. -   5. Traub, R., C. L. Wisseman & A. Farhang-Azad. 1978. The ecology of     murine typhus-a critical review. Trop. Dis. Bull. 75: 237-317 -   6. Jones, S L, Athan E, O□Brien D, Graves S R, Ngyuyen C, Stenos J.     Murine typhus: the first reported case from Victoria. Med. J Aust.     2004 May 3; 180(9):482. -   7. Lledo L, Gegundez I, Ruiz E, Rodriguez L, Bacellar F, Saz J V.     Rickettsia typhi infection in wild rodents from central Spain. Ann     Trop Med. Parasitol. 2003 June; 97(4):411-4. -   8. Richards A L, Rahardjo E, Rusjdi A F, Kelly D J, Dasch G A,     Church C J, Bangs MJ. Evidence of Rickettsia typhi and the potential     for murine typhus in Jayapura, Irian Jaya, Indonesia. Am J Trop Med.     Hyg. 2002 April; 66(4):431-4. -   9. Walker, D. H., F. M. Parks, T. G. Betz, et al. 1989.     Histopathology and immunohistologic demonstration of the     distribution of Rickettsia typhi in fatal murine typhus. Am. J.     Clin. Pathol. 91: 720-724 -   10. La Scola B, Rydkina L, Ndihokubwayo J B, Vene S, Raoult D.     Serological differentiation of murine typhus and epidemic typhus     using cross-adsorption and Western blotting. Clin Diagn Lab Immunol.     2000 July; 7(4):612-6. -   11. La Scola B, Raoult D. Laboratory diagnosis of rickettsioses:     current approaches to diagnosis of old and new rickettsial diseases.     J Clin Microbiol. 1997 November; 35(11):2715-27. Review. -   12. Weil E., and A. Felix. 1916. Zur serologischen Diagnose des     Fleckfiebers. Wien. Klin. Wochenschr. 29:33-35. -   13. Ormsbee R, Peacock M, Philip R, Casper E, Plorde J, Gabre-Kidan     T, Wright L. Serologic diagnosis of epidemic typhus fever. Am J     Epidemiol. 1977 March; 105(3):261-71. -   14. Shepard C C, Redus M A, Tzianabos T, Warfield D T. Recent     experience with the complement fixation test in the laboratory     diagnosis of rickettsial diseases in the United States. J Clin     Microbiol. 1976 September; 4(3):277-83. -   15. Philip, R N, Casper E A, Ormsbee R A, Peacock M G, Burgdorfer W.     Microimmunofluorescence test for the serological study of Rocky     mountain spotted fever and typhus. J. Clin Microbiol. 3:51-61. -   16. Shirai A, Dietel J W, Osterman J V. Indirect hemagglutination     test for human antibody to typhus and spotted fever group     rickettsiae. J Clin Microbiol. 1975 November; 2(5):430-7. -   17. Eremeeva, M E., N M. Balayeva, D. Raoult. Serological response     of patients suffering from primary and recrudescent typhus:     comparison of complement fixation reaction, Weil-Felix test,     microimmunofluorescence, and immunoblotting. Clin. Diagn. Lab.     Immunol. 1994, 1:318-324. -   18. Kelly D J, Chan C T, Paxton H, et al. Comparative evaluation of     a commercial enzyme immunoassay for the detection of human antibody     to Rickettsia typhi. Clin Diagn Lab Immunol 1995; 2:356-60. -   19. Jiang J, Temenak J J, Richards A L. Real-time PCR duplex assay     for Rickettsia prowazekii and Borrelia recurrentis. Ann N Y Acad.     Sci. 2003 June; 990:302-10. -   20. Kodama K, Senba T, Yamauchi H, Chikahira Y, Katayama T, Furuya     Y, Fujita H, Yamamoto S. Fulminant Japanese spotted fever     definitively diagnosed by the polymerase chain reaction method. J     Infect Chemother. 2002 September; 8(3):266-8. -   21. Palmer, E L., M L. Martin, and L. Mallavia. Ultrastructure of     the surface of Rickettsia prowazekii and Rickettsia akari. Appl.     Microbiol. 1974, 28:713-716. -   22. Ching, W M., M. Carl, and G A. Dasch. Mapping of monoclonal     antibody binding sites on CNBr fragments of the S-Layer protein     antigens of Rickettsia typhi and R. Prowazekii. Mol. Immunol. 1992,     29:95-105. -   23. Ching, W M., G A. Dasch, M. Carl and M E. Dobson. Structural     analyses of the 120 Kda serotype protein antigens (SPAs) of typhus     group rickettsiae: comparison with other S-layer proteins. Anna.     N.Y. Acad. Sci. 1990, 590:334-351. -   24. Dasch, G A. Isolation of species-specific protein antigens of     Rickettsia typhi and Rickettsia prowazekii for immunodiagnosis and     immnuoprophylzxis. J. Clin. Microbiol. 1981, 14:333-341. -   25. Dasch. G A., J R. Samms, and J C. Williams. Partial purification     and characterization of the major species-specific protein antigens     of Rickettsia typhi and rickettsia prowazekii identified by rocket     immunoelectrophoresis. Infect. Immun. 1981, 31:276-288. -   26. Bourgeois, A L., and G A. Dasch. The species-specific surface     protein antigens of Rickettsia typhi: immunogenicity and protective     efficacy in guinea pigs. P. 71-80. In W. Burgdorfer and R L. Anacker     (ed), Rickettsia and rickettsial diseases. Academic Press, New York. -   27. Carl. M., and G A. Dasch. The importance of crystalline surface     layer protein antigens of rickettsiae in T cell immunity. J.     Autoimmun, 1989, 2:81-91. -   28. Dasch, G A., and A L. Bourgeois. Antigens of the typhus group of     rickettsiae: importance of the speciese-specific surface protein     antigens in eliciting immunity, p 61-70. In W. Burgdorfer and R L.     Anacker (ed), Rickettsia and rickettsial diseases. Academic Press,     New York. -   29. Dasch. G A., J P. Burans, M E. Dobson, F M. Rollwagen, and J.     Misiti. Approaches to the subunit vaccines against the typhus     rickettsiae, Rickettsia typhi and Rickettsia prowazekii, 251-256.     In D. Schlessinger (ed), Microbiology-1984, American Society for     Microbiology, Washington, D.C. -   30. Ching, W M., H. Wang, J. Davis, and G A. Dasch. Amino acid     analysis and multiple methylation of lysine residues in the surface     protein antigen of Rickettsia prowazekii, p. 307-14. In R H.     Angeletti (ed), Techiques in protein chemistry IV. Academic Press,     San Diego. -   31. Ching W M, Ni Y S, Kaplan H, Zhang Z, and Dasch G A (1997).     Chemical methylation of E. coli expressed Rickettsia typhi protein     increases its seroreactivity. Thirteenth Sesqui-Annual Meeting of     American Society for Rickettsiology, Champion, Pa. abstract #40. -   32. Chao C C, Wu S L, and Ching W M. Using LC-MS with De novo     Software to Fully Characterize the Multiple Methylations of Lysine     Residues in a Recombinant Fragment of an Outer Membrane Protein from     a Virulent Strain of Rickettsia prowazekii. Biochimica -   33. Ching W M, Zhang Z, Dasch G A, and Olson J G. Improved diagnosis     of typhus rickettsiae using a chemically methylated recombinant     s-layer protein fragment. Amer. Soc. Biochem. & Mole. Biol./Amer.     Soc. Pham. & Exper. Therap. 2000. Boston, MA. abstract # 463. 

1. A isolated Rickettsia typhi assay reagent comprising an antigen containing one or more polypeptide fragments of OmpB, wherein said polypeptide fragment of OmpB is Fragment K with the amino acid sequence of SEQ ID No. 4, encoded by the nucleotide sequence of SEQ ID No.
 3. 2. The assay reagent of claim 1, wherein said polypeptide fragments are native or recombinant.
 3. The of claim 1, wherein said polypeptide fragment of OmpB is either methylated or unmethylated. 